FRINK Linked Data Fragments server

Matches in SemOpenAlex for { <https://semopenalex.org/work/W2009758972> ?p ?o ?g. }

• W2009758972 endingPage "107" @default.
• W2009758972 startingPage "99" @default.
• W2009758972 abstract "Novel Ni–Mo/activated carbon (AC) hydrotreating catalysts were prepared and evaluated for upgrading heavy vacuum gas oil (HVGO). The AC supports were derived from Alberta oil sand petroleum coke, i.e. fluid coke and/or delayed coke, hereafter referred to as OSP coke, through a chemical process. The BET surface area was as high as 2194 m2/g for the fluid coke derived AC and 2357 m2/g for the delayed coke derived AC. Both ACs contained a large number of micropores with pore volume as high as 1.2 cm3/g. Ni and Mo based active component precursors could be easily loaded on the activated carbon supports by chemical impregnation of nickel nitrate and ammonium molybdate followed by calcination in nitrogen at 773 K without further modification or oxidation treatment to the activated carbons. Scanning electron microscopy (SEM) observation showed highly porous surface structure of the bare activated carbon supports and well dispersed metal (oxide) precursor nanoparticles of 30–50 nm loaded on the AC supports. For comparison, two reference catalysts were also prepared by the same procedure but using commercial activated carbon and porous alumina as supports. After catalyst activation by sulfiding, the hydrotreating performance of the prepared catalysts was evaluated in a magnetically stirred autoclave with a HVGO feedstock to examine their hydrodesulfurization (HDS) and hydrodenitrogenation (HDN) activities. Two commercial hydrotreating catalysts were also tested and compared under similar conditions with the same feed. The results showed that the catalysts based on the activated carbon supports prepared from OSP coke had better hydrotreating performance than the other catalysts. Scanning transmission electron microscopy (STEM) characterization of the catalysts after activation showed that small particles of nanostructure (2–5 nm in size) were evenly embedded in the carbon matrix except for some bigger particles that were located on the catalyst surface. Energy dispersive X-ray (EDX) spectroscopy revealed that these particles were composed of Ni, Mo and S elements. The dispersed nanoparticles formed the active sites and were responsible for the observed high HDS and HDN activity. Elemental analysis and surface characterization of the spent catalysts showed that the formation of coke precursors was favored on the alumina supported catalyst, which resulted in catalyst deactivation." @default.
• W2009758972 created "2016-06-24" @default.
• W2009758972 creator A5014113290 @default.
• W2009758972 creator A5053997706 @default.
• W2009758972 creator A5060784156 @default.
• W2009758972 creator A5069956504 @default.
• W2009758972 creator A5074257037 @default.
• W2009758972 date "2012-10-01" @default.
• W2009758972 modified "2023-10-17" @default.
• W2009758972 title "Preparation and evaluation of hydrotreating catalysts based on activated carbon derived from oil sand petroleum coke" @default.
• W2009758972 cites W1970476210 @default.
• W2009758972 cites W1976959722 @default.
• W2009758972 cites W1979571033 @default.
• W2009758972 cites W1992928083 @default.
• W2009758972 cites W1994346306 @default.
• W2009758972 cites W1998171980 @default.
• W2009758972 cites W1999347518 @default.
• W2009758972 cites W2001814671 @default.
• W2009758972 cites W2009079017 @default.
• W2009758972 cites W2013743094 @default.
• W2009758972 cites W2015948162 @default.
• W2009758972 cites W2020844486 @default.
• W2009758972 cites W2020995003 @default.
• W2009758972 cites W2021432654 @default.
• W2009758972 cites W2021927330 @default.
• W2009758972 cites W2026415186 @default.
• W2009758972 cites W2034780854 @default.
• W2009758972 cites W2046904933 @default.
• W2009758972 cites W2050172755 @default.
• W2009758972 cites W2051380824 @default.
• W2009758972 cites W2053540002 @default.
• W2009758972 cites W2059359869 @default.
• W2009758972 cites W2062195250 @default.
• W2009758972 cites W2065583711 @default.
• W2009758972 cites W2067528457 @default.
• W2009758972 cites W2073780251 @default.
• W2009758972 cites W2075905178 @default.
• W2009758972 cites W2082611762 @default.
• W2009758972 cites W2085461664 @default.
• W2009758972 cites W2086619515 @default.
• W2009758972 cites W2109148138 @default.
• W2009758972 cites W2120294882 @default.
• W2009758972 cites W2121396653 @default.
• W2009758972 cites W2123526711 @default.
• W2009758972 cites W2135783306 @default.
• W2009758972 cites W2136857309 @default.
• W2009758972 cites W250436241 @default.
• W2009758972 doi "https://doi.org/10.1016/j.apcata.2012.07.014" @default.
• W2009758972 hasPublicationYear "2012" @default.
• W2009758972 type Work @default.
• W2009758972 sameAs 2009758972 @default.
• W2009758972 citedByCount "28" @default.
• W2009758972 countsByYear W20097589722014 @default.
• W2009758972 countsByYear W20097589722015 @default.
• W2009758972 countsByYear W20097589722016 @default.
• W2009758972 countsByYear W20097589722017 @default.
• W2009758972 countsByYear W20097589722018 @default.
• W2009758972 countsByYear W20097589722019 @default.
• W2009758972 countsByYear W20097589722020 @default.
• W2009758972 countsByYear W20097589722021 @default.
• W2009758972 countsByYear W20097589722022 @default.
• W2009758972 countsByYear W20097589722023 @default.
• W2009758972 crossrefType "journal-article" @default.
• W2009758972 hasAuthorship W2009758972A5014113290 @default.
• W2009758972 hasAuthorship W2009758972A5053997706 @default.
• W2009758972 hasAuthorship W2009758972A5060784156 @default.
• W2009758972 hasAuthorship W2009758972A5069956504 @default.
• W2009758972 hasAuthorship W2009758972A5074257037 @default.
• W2009758972 hasConcept C104779481 @default.
• W2009758972 hasConcept C127404614 @default.
• W2009758972 hasConcept C127413603 @default.
• W2009758972 hasConcept C13965031 @default.
• W2009758972 hasConcept C140205800 @default.
• W2009758972 hasConcept C150394285 @default.
• W2009758972 hasConcept C159985019 @default.
• W2009758972 hasConcept C161790260 @default.
• W2009758972 hasConcept C178790620 @default.
• W2009758972 hasConcept C179104552 @default.
• W2009758972 hasConcept C185592680 @default.
• W2009758972 hasConcept C192562407 @default.
• W2009758972 hasConcept C197129369 @default.
• W2009758972 hasConcept C2778570275 @default.
• W2009758972 hasConcept C2779647737 @default.
• W2009758972 hasConcept C2780385392 @default.
• W2009758972 hasConcept C27923307 @default.
• W2009758972 hasConcept C42360764 @default.
• W2009758972 hasConcept C7082614 @default.
• W2009758972 hasConceptScore W2009758972C104779481 @default.
• W2009758972 hasConceptScore W2009758972C127404614 @default.
• W2009758972 hasConceptScore W2009758972C127413603 @default.
• W2009758972 hasConceptScore W2009758972C13965031 @default.
• W2009758972 hasConceptScore W2009758972C140205800 @default.
• W2009758972 hasConceptScore W2009758972C150394285 @default.
• W2009758972 hasConceptScore W2009758972C159985019 @default.
• W2009758972 hasConceptScore W2009758972C161790260 @default.
• W2009758972 hasConceptScore W2009758972C178790620 @default.
• W2009758972 hasConceptScore W2009758972C179104552 @default.
• W2009758972 hasConceptScore W2009758972C185592680 @default.

• next